Recent resources for Quantum Entanglementhttp://einsteinish.com/resource/topic/quantum-entanglement/2019-01-21T17:10:04Zfeed for recent resources shared on einsteinish for Quantum EntanglementQuantum Entanglement and the Great Bohr-Einstein Debate | Space Time | PBS Digital Studioshttp://einsteinish.com/resource/285/
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<td>Resource Type:</td> <td>Video</td>
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<a href="/resource/topic/quantum-entanglement/" class="">Quantum Entanglement</a>
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<td>Submitted by:</td>
<td><a href="/profile/pygoogle/">pygoogle</a></td>
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<td>Date Submitted</td> <td>Tue 31 Jan 2017</td>
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<h2>Description:</h2>
<p>Albert Einstein strongly disagreed with Niels Bohr when it came to Bohr’s interpretation of quantum mechanics. Quantum entanglement settled the argument once and for all.</p>
Quantum Entanglement & Spooky Action at a Distancehttp://einsteinish.com/resource/283/
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<td>Resource Type:</td> <td>Video</td>
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<a href="/resource/topic/quantum-entanglement/" class="">Quantum Entanglement</a>
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<td>Submitted by:</td>
<td><a href="/profile/pygoogle/">pygoogle</a></td>
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<td>Date Submitted</td> <td>Tue 31 Jan 2017</td>
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<h2>Description:</h2>
<p>Does quantum entanglement make faster-than-light communication possible?
What is NOT random? http://bit.ly/NOTrandoVe</p>
<p>First, I know this video is not easy to understand. Thank you for taking the time to attempt to understand it. I've been working on this for over six months over which time my understanding has improved. Quantum entanglement and spooky action at a distance are still debated by professors of quantum physics (I know because I discussed this topic with two of them).</p>
<p>Does hidden information (called hidden variables by physicists) exist? If it does, the experiment violating Bell inequalities indicates that hidden variables must update faster than light - they would be considered 'non-local'. On the other hand if you don't consider the spins before you make the measurement then you could simply say hidden variables don't exist and whenever you measure spins in the same direction you always get opposite results, which makes sense since angular momentum must be conserved in the universe.</p>
<p>Everyone agrees that quantum entanglement does not allow information to be transmitted faster that light. There is no action either detector operator could take to signal the other one - regardless of the choice of measurement direction, the measured spins are random with 50/50 probability of up/down.</p>
Wiki's quantumhttp://einsteinish.com/resource/8/
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<td>Resource Type:</td> <td>Online</td>
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<a href="/resource/topic/quantum-entanglement/" class="">Quantum Entanglement</a>
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<td>Submitted by:</td>
<td><a href="/profile/sfvue/">sfvue</a></td>
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<td>Date Submitted</td> <td>Sat 16 Jan 2016</td>
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<h2>Description:</h2>
<p>Quantum entanglement is a physical phenomenon that occurs when pairs or groups of particles are generated or interact in ways such that the quantum state of each particle cannot be described independently — instead, a quantum state may be given for the system as a whole.</p>